WO2012156202A1 - Communication system and corresponding method, computer program, and storage means - Google Patents

Abstract

The invention relates to a communication system comprising communication nodes communicating via multi-frequency, time division multiple access frames. The nodes form a hierarchical cellular radio network that defines hierarchical levels which each include a base and at least one handset. The communication nodes are enabled to communicate via the base of the hierarchical level thereof. A master node comprises: a means (4.2) for selecting, in each of the frames, a transmission resource that is common to said communication nodes; a means (4.3) for broadcasting to the communication nodes, through the hierarchical levels via the respective bases thereof, information representative of the selected common transmission resource. The system is suitable for enabling said communication nodes to broadcast messages via the selected common transmission resource.

Description

 Communication system, and method, computer program and corresponding storage means

The present invention relates to the field of cellular radio communication systems and more particularly to communication systems based on multiple accesses by time division and frequency division.

 Cellular radio communication systems allow devices, called mobile handsets or terminals, to communicate with each other via at least one other device, called a base. A device, whether a handset or a base, is more generally called a communication node.

 Each base manages a cell and periodically sends a signal, called beacon, which allows the handsets in the coverage area of the cell to synchronize with the base to establish communications and exchange system management information. Communication.

Such known radio communication systems use a Time Division Multiple Access (TDMA) time division multiple access mechanism. In these systems, time is divided into frames for framing the communication. Each frame is itself divided into time slots (time slot in English) of predefined duration, to share the access time to the transmission medium between the communication nodes. Such systems may furthermore use a Frequency Division Multiple Access (FDMA) frequency division multiple access mechanism. For example, improved digital wireless telecommunications systems DECT (registered trademark), for Digital Enhanced Cordless Telecommunications, as specified in the ETS 300 175 series of documents published by the ETSI (European Telecommunications Standards Institute), use TDMA and FDMA transmission principles.

 Such TDMA and FDMA communication systems can be mobile.

That is, handsets and bases can be mobile. In these mobile TDMA and FDMA communication systems, the transmission conditions between the communication nodes may change rapidly, for example by the appearance of a phenomenon of signal jamming or fading (English fading) of the signal by the appearance of an obstacle. between the communication nodes. The communication channels established between the communication nodes can then be interfered with in communication or even become unusable.

 Although cellular radio communication standards provide for an automatic transfer mechanism (handover in English) from one handset to another base, its implementation is not fast enough to counteract so-called rapid attenuation phenomena. fast fading or fast shadowing.

 In addition, such fast attenuation or fast masking phenomena can be detected only by a subset of the communication nodes. Such a situation must be notified to the rest of the communication system, so that a redefinition of the communication channels and the base-combined roles can be implemented as soon as possible. The automatic transfer mechanisms previously mentioned are not sufficiently reactive in this type of situation.

It is desirable to overcome these various disadvantages of the state of the art. It is in particular desirable to provide a solution that makes it possible to improve the responsiveness of communication systems composed of mobile communication nodes, and more particularly in the context of TDMA and FDMA type transmissions, during rapid changes in the transmission conditions. In particular, it is desirable to provide a solution that makes it possible to improve the reactivity of such communication systems when interference, fast attenuation or fast hiding phenomena occur.

 It is particularly desirable to provide a solution that allows a handset to synchronize quickly on a new base, when communication with the base on which it was attached is broken.

 In particular, it is desirable to provide a solution which makes it possible to rapidly broadcast, in such communication systems, information of change of transmission conditions.

 The invention relates to a communication system comprising communication nodes communicating via time division multiple access and frequency division type frames, said nodes forming a hierarchical cellular radio network defining hierarchical levels each comprising a base and a least one handset, said system being adapted so that the communication nodes are allowed to communicate via the base of their hierarchical level. The system is such that a communication node, said master node, comprises: means for selecting in each of said frames a transmission resource common to said communication nodes, said transmission resource common to the network neighborhood; means for distributing to said communication nodes, through the hierarchical levels via their respective bases, information representative of the selected common transmission resource. The system is further adapted to allow said communication nodes to broadcast messages via the selected common transmission resource. Thus, by allowing the communication nodes to transmit data so as to broadcast via the transmission resource common to the network neighborhood, in addition to communications via the base of their hierarchical level, the communication system is more responsive.

According to a particular embodiment, said master node comprises means for obtaining information representative of transmission conditions between said communication nodes and means for selecting the transmission resource common to the network neighborhood are adapted to make the selection according to said information. obtained. Thus, the communication system is even more reactive when appearing interference phenomena, fast attenuation or fast masking. According to a particular embodiment, said communication nodes comprise means for determining transmission conditions in said communication system and means for transmitting messages comprising information representative of transmission conditions, or of change of transmission conditions either via the transmission resource common to the network neighborhood, either via the base of their hierarchical level.

 According to a particular embodiment, said communication nodes comprise means for broadcasting via the transmission resource common to the network neighborhood messages comprising synchronization information identifying a resource of said frames used to transmit a beacon signal. Thus, a node for which the communication channel with the base of its hierarchical level is broken can be reinserted as quickly as possible in the system.

 According to a particular embodiment, said communication nodes comprising handset and base functions, said communication nodes comprise: means for detecting a risk of loss of connectivity with a communication node; means for activating a beacon signal, when a risk of loss of connectivity is detected; means for broadcasting via the transmission resource common to the network neighborhood a message comprising synchronization information identifying a resource of said frames, used to transmit said beacon signal. Thus, the connectivity of the communication system is improved.

 According to a particular embodiment, the base of each hierarchical level comprises means for authorizing the communication nodes of its hierarchical level to broadcast messages via a common transmission resource at said hierarchical level.

 According to a particular embodiment, the common transmission resource at each hierarchical level corresponds to a resource of said frames having a predefined position relative to a resource used by the base of said hierarchical level to transmit a beacon signal. Thus, the use of resources is optimized.

According to a particular embodiment, the base of each hierarchical level comprises means for changing the resource of said frames, used to transmit a beacon signal, according to messages received via the resource of common transmission at its hierarchical level or via the transmission resource common to the network neighborhood. Thus, the communication system is more responsive.

 According to a particular embodiment, said system is adapted so that the bases transmit their beacon signal in a time interval distinct from each time interval defining the transmission resource common to the network neighborhood.

 The invention also relates to a method of communication in a communication system comprising communication nodes communicating via time division multiple access type frames, said nodes forming a hierarchical cellular radio network defining hierarchical levels each comprising a base and at least one handset, said system being adapted so that the communication nodes are allowed to communicate via the base of their hierarchical level. The method is such that a communication node, said master node, performs the steps of: selecting in each of said frames a transmission resource common to said communication nodes, said transmission resource common to the network neighborhood; broadcasting to said communication nodes, through the hierarchical levels via their respective bases, information representative of the selected common transmission resource. The method is further such that said communication nodes are allowed to broadcast messages via the selected common transmission resource.

 The invention also relates to a computer program, which can be stored on a medium and / or downloaded from a communication network, in order to be read by a computer system or a processor. This computer program includes instructions for implementing the method mentioned above, when said program is executed by the computer system or the processor. The invention also relates to storage means comprising such a computer program.

 The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of an exemplary embodiment, said description being given in relation to the attached drawings, among which:

FIG. 1 schematically illustrates a frame structure in which the invention can be implemented; FIG. 2 schematically illustrates a communication system in which the invention can be implemented;

 FIG. 3 schematically illustrates a communication node architecture of the communication system of FIG. 2;

 FIG. 4 schematically illustrates an algorithm for setting up a transmission resource common to the network neighborhood;

 FIG. 5 schematically illustrates a first algorithm for using the transmission resource common to the network neighborhood;

 FIG. 6 schematically illustrates a second algorithm for using the transmission resource common to the network neighborhood;

 FIG. 7 schematically illustrates a resynchronization algorithm using information broadcast via the transmission resource common to the network neighborhood;

 FIG. 8 schematically illustrates a network neighborhood connectivity improvement algorithm using information transmitted via the transmission resource common to the network neighborhood.

 In order to increase the reactivity of TDMA type communication systems to changes in transmission conditions, it is proposed to reserve in each TDMA frame a transmission resource common to the network neighborhood, intended to allow each of the communication nodes to broadcast information in mode not connected {connectionless mode in English). This transmission resource common to the network neighborhood is selected by a predefined node of the communication system preferably according to the transmission conditions, and is therefore, in this case, likely to vary over time. This transmission resource common to the network neighborhood thus enables any communication node to broadcast synchronization, topology management, network neighborhood detection and / or transmission condition change detection information in the communication system, independently of one another. from the base to which he is attached.

Network Neighborhood is understood to mean the entire communication system, that is to say the set of communication nodes that are authorized to communicate via the same frame. The establishment and use of this transmission resource common to the network neighborhood in each TDMA frame is detailed below in the illustrative framework of a DECT (registered trademark) type communication system.

 Fig. 1 schematically illustrates a frame structure 1.1 in which the invention can be implemented. The representation of FIG. 1 has two axes: along the vertical axis ordinates, different carrier frequencies are represented; and along the horizontal axis of the abscissae, different consecutive time intervals are represented. The representation of FIG. 1 illustrates, for example, a frame according to the TDD (Time Division Duplex) communication principles, TDMA and FDMA that can be found in DECT (registered trademark) type communication systems.

 The frame 1.1 is of duration equal to 10 ms and is divided, according to the time axis, in a first part 1.2 devoted to the downlink traffics (downlink in English) and a second part 1.3 devoted to the uplink traffics (English). Downstream traffic is transmitted from one base to at least one handset, while upstream traffic is transmitted by a handset to a base. It is said that the communications are half-duplex (half-duplex), in the sense that the downstream and upstream communications are not simultaneous, but spread over different time intervals.

 In the representation of FIG. 1, the first 1.2 and second 1.3 parts are of the same duration. Each of these parts is further broken down into twelve elementary time intervals of the same duration. In the representation of FIG. 1, the frame 1.1 is further divided, according to the frequency axis, into ten carrier frequencies.

 Thus, the frame 1.1 comprises elementary communication units 1.6 which respectively correspond to a carrier frequency and to a time interval. Each elementary communication unit 1.6 is then defined by a single frequency / time interval pair. The frame 1.1 shown in FIG. 1 thus comprises two hundred and forty elementary communication units 1.6.

When two nodes communicate, a transmission channel is defined as a pair of basic communication units 1.6, one unit per direction of communication. A first unit in the first part 1.2 of the frame 1.1 and a second unit in the second part 1.3 of the frame 1.1. Typically, these basic communication units 1.6 are corresponding, i.e. they use the same carrier frequency and are separated by twelve time intervals. elementary. This is the case of elementary communication units 1.6 marked with a cross in FIG. 1, i.e. those corresponding to the ninth and twenty-first time intervals on the seventh carrier frequency.

 Each basic communication unit 1.6 allows the transmission of signals in the form of a data packet, which may be composed of a header field which contains signaling and protocol information and a data field. payload data which contains the actual data exchanged. Typically, the useful data field contains the audio samples during a voice type communication.

 To allow the connection of a handset to a base, this base emits a signal called beacon (beacon in English). This signal uses one of the basic communication units 1.6 of the first part 1.2 of the frame 1.1. This signal is emitted periodically, at each frame, and contains the signaling and synchronization information necessary for the handset to connect and synchronize on the base so that it can communicate with it. Typically, the beacon signal transmitted by a base to allow connection of handsets consists of signaling information contained in the header field of a data packet, and the useful data field is then meaningless.

 Fig. 2 schematically illustrates a hierarchical communication system in which the invention can be implemented. Such a communication system can be intended for a set of individuals, at least a part of which is mobile, and which respectively relate to themselves communication devices 2.1, 2.2, 2.3, 2.4, 2.5 and 2.6, also called nodes. Communication. The communications between the node are carried out by means of frames in the format of the frame 1.1.

 Each of the communication nodes 2.1, 2.2, 2.3, 2.4, 2.5 and 2.6 preferably has handset and base functions.

In the representation of FIG. 2, the communication system is in a situation where: the communication node 2.1 functions as a base for the communication nodes 2.2 and 2.3; the communication node 2.2 only functions as a handset; the communication node 2.3 functions as a handset for the communication node 2.1 and as a base for the communication nodes 2.4 and 2.5; the communication node 2.5 functions only as a handset; and, the communication node 2.4 functions as a handset for the communication node 2.3 and as a base for the communication node. communication 2.6. Thus, data can be relayed by a node to put, or maintain, in relation to at least two other nodes. There is thus a communication channel 2.10 between the nodes 2.1 and 2.2, a communication channel 2.11 between the nodes 2.1 and 2.3, a communication channel 2.12 between the nodes 2.3 and 2.4, a communication channel 2.13 between the nodes 2.3 and 2.5 , and a communication channel 2.14 between nodes 2.4 and 2.6. We can also talk about communication links.

 Except for the higher hierarchical communication node 2.1, called master, each other communication node is attached to a base, and can itself serve as a base. A communication tree forming a chaining of the communication nodes is thus obtained, allowing all of these communication nodes to have the same clock reference. The set formed by a communication node acting as a base and the communication nodes attached to it is called group or hierarchical level.

 The communication nodes of each group can communicate with each other through the group base. Four basic communication units 1.6 of the frame 1.1 are then necessary to implement such communication. Information can also be exchanged between groups by going up and / or down hierarchically the communication tree via the bases of the groups. In these two cases, each base serves as a relay between the communication nodes, either within the group for which it acts as a base, or between the group in which it acts as a base and that, if exists, in which it acts as a combined. In other words, the communication system is a hierarchical cellular radio network defining hierarchical levels each comprising a base and at least one handset, the system being adapted so that the communication nodes are authorized to communicate via the base of their base. hierarchical level.

The transmission resource common to the network neighborhood is then an alternative information transmission means to the upward and downward hierarchies of the communication tree. The transmission resource common to the network neighborhood makes it possible to avoid experiencing congestions that may appear at the level of the bases of the communication system, and this by providing any communication node with a means of broadcasting independent of the base to which it is attached. . The individuals being mobile, the transmission conditions between the communication nodes can change rapidly, for example by appearance of a phenomenon of signal interference or fading of the signal by appearance of obstacle between the communication nodes. Communication channels 2.10, 2.11, 2.12, 2.13 and 2.14 can then be interfered with or even become unusable.

 For example, following a signal scrambling, the communication channel 2.14 becomes unusable and the communication node 2.6, acting as a handset, can no longer synchronize on the communication node 2.4, acting as a base. It is then necessary for the communication node 2.6 to synchronize with another communication node acting as a base.

 The handset can then use the information broadcast via the common transmission resource to the network neighborhood to accelerate its resynchronization to a base. The use of the resource common to the network neighborhood for broadcasting such information is detailed below in relation to FIG. 5. This eliminates the need to scan the entire transmission spectrum to detect a basic tag that it could attach to. Such use of the information broadcast via the transmission resource common to the network neighborhood is described below in relation to FIG. 7.

 The handset may also use the common resource in the network neighborhood to broadcast a discovery message, called a hello message, to indicate to other communication nodes that it is searching for a base to attach to. The use of the resource common to the network neighborhood to broadcast such a message is detailed below in relation to FIG. 5.

 In addition, such fast attenuation or fast masking phenomena can be detected only by a subset of the communication nodes. Such a situation must be notified to the rest of the communication system, so that a redefinition of the communication channels and the base-combined roles can be implemented as soon as possible.

The handset can then use the common transmission resource in the network neighborhood to broadcast information about the transmission conditions and thus accelerate their dissemination in the communication system. Such use of the information broadcast via the transmission resource common to the network neighborhood is described below in relation to FIG. 6. Such use of the information broadcast via the common neighborhood transmission resource is particularly useful when a phenomenon of scrambling, fast masking or fast attenuation occurs between the handset and the base to which it is attached.

 Such use of the information broadcast via the transmission resource common to the network neighborhood is also particularly useful when the communication node considered acts as a base, this node is congested, and a phenomenon of jamming, fast masking or Fast attenuation occurs between this node and the base to which it is attached. Indeed, in a particular embodiment, each communication node can transmit or receive only on a single carrier frequency at each time interval. Thus, when a communication node acting as a base is highly stressed, it has little or no opportunity to detect beacon transmissions by the other communication nodes. If the communication with the base to which it is attached breaks, it will be necessary for it to browse all the carrier frequencies in search of tags, thus causing its disconnection of the communication system during several TDMA frames.

 Fig. 3 schematically illustrates a communication node architecture of the communication system. This architecture comprises, connected by a communication bus 3.1: a processor, microprocessor, microcontroller (noted μο) or CPU (Central Processing Unit in English or Central Processing Unit in French) 3.2; random access memory RAM (Random Access Memory in English or Random Access Memory in French) 3.3; a ROM (Read Only Memory in English or Mémoire à Lire Seul in French) 3.4; a 3.5 medium storage drive, such as a SD card reader (Secure Digital Card in English or Secured Digital Card in French); radio interface means 3.6; and human-machine interface means 3.7.

The microcontroller 3.2 is capable of executing instructions loaded in the RAM 3.3 from the ROM 3.4, an external memory (not shown), a storage medium, such as an SD card or the like, or a communication network. When the communication node is powered up, the microcontroller 3.2 is able to read instructions from RAM 3.3 and execute them. These instructions form a computer program, which causes the implementation, by the micro controller 3.2, all or part of the algorithms described below in relation to FIGS. 4-7.

 All or part of the algorithms described below in relation to FIGS. 4 to 7 can be implemented in software form by executing a set of instructions by a programmable machine, such as a DSP (Digital Signal Processor in English or Digital Signal Processing Unit in French) or a microcontroller, or be implemented in hardware form by a machine or a dedicated component, such as an FPGA (Field Programmable Gate Array) or an ASIC (Application-Specific Integrated Circuit) Specific to an Application in French).

 Fig. 4 schematically illustrates an algorithm for setting up the transmission resource common to the network neighborhood.

 The algorithm illustrated in FIG. 4 is implemented by a dedicated node of the communication system. It is preferably implemented by the higher hierarchy node, the master node, that is to say the communication node 2.1 in the representation of FIG. 2. The master node is the one in the network neighborhood, which acts only as a base, the other nodes of communication acting as combined, or as base and combined. In an alternative embodiment, this master node may be elected from among the nodes of the communication system, in particular to take into account the fact that, following an appearance or disappearance of a phenomenon of jamming, fast masking or attenuation fast, the communication system can be split into two or, respectively, two communication systems can be merged.

In a step 4.1, the master node 2.1 determines the conditions of transmission in the communication system. This step can be performed by analyzing the signals received by the master node 2.1 via its interface 3.6 and / or from information provided by other nodes of the communication system. Such information can be provided either in point-to-point mode (unicast in English) by the communication nodes of the group of the master node, or in broadcast mode (broadcast in English) via the transmission resource common to the network neighborhood previously allocated. . When this information is provided by the communication nodes of the group of the master node, they can be information relayed by these nodes on behalf of groups of lower hierarchical level. The master node 2.1 thus determines, in the frame 1.1, the basic communication units 1.6 which, according to the transmission conditions, can be used by all the nodes of the communication system.

 In a next step 4.2, the master node 2.1 selects the transmission resource common to the network neighborhood, according to the transmission conditions determined in step 4.1.

 The transmission resource common to the network neighborhood may be a single elementary communication unit 1.6 or several basic communication units 1.6, which can then be contiguous or disjoint in the representation of FIG. 1.

 In a subsequent step 4.3, the master node 2.1 notifies the other nodes of the communication system which elementary unit (s) 1.6 communication (s) are allocated to form the transmission resource common to the network neighborhood. Preferably, this notification is performed by the master node 2.1 in the beacon that it transmits to each frame 1.1. This notification is then relayed by each of the communication nodes of the group of the master node 2.1 and which also acts as a base for another group. This notification is then relayed in these other groups through tags transmitted by the bases of these groups. The notification can be relayed again in order to be broadcast throughout the communication tree via the beacons issued by the bases of the groups.

 The communication nodes can thus be free from the hierarchical character of the communication tree and transmit messages and information without passing through the base to which it is attached, and this by using the transmission resource common to the network neighborhood. The set of communication nodes is thus authorized to access the transmission resource common to the network neighborhood selected and notified by the master node 2.1.

 In a particular embodiment, step 4.1 is performed for each frame 1.1 and a new transmission resource common to the network neighborhood is selected and then notified, in the event of a change in transmission conditions involving at least one elementary unit of communication 1.6 of the transmission resource common to the network neighborhood previously allocated is no longer usable.

Fig. 5 schematically illustrates a first algorithm for using the transmission resource common to the network neighborhood. According to a first exemplary embodiment, the transmission resource common to the network neighborhood is used to broadcast messages comprising synchronization information and / or information concerning the topology of the network constituted by the communication nodes. In a step 5.1, the communication node considered generates such a message. This message, called neighborhood, may include:

 a field comprising an identifier of the communication node considered;

a field comprising an identifier of the group to which the communication node considered belongs;

 a field comprising an elementary communication unit identifier

1.6 in which the communication node considered transmits a beacon, when the communication node considered acts as a base;

 a field comprising a list of identifiers of a predefined number of communication nodes which are closest to the communication node in question, that is to say those for which the energy of the signals received is the highest;

 a field comprising an identifier of the base to which the communication node in question is possibly attached;

 a field comprising a signal transmission quality indicator, or distance estimation indicator, between the communication node considered and the base to which it is possibly attached;

 a field including an indication of the size of the cell, when the communication node under consideration acts as a base.

 When a communication node receives such messages via the transmission resource common to the network neighborhood, this allows it to be located within the communication system and to know its network neighbors, that is to say those with which a direct communication can be established. A use of these messages by a communication node to resynchronize is described below in relation to FIG. 7.

In a next step 5.2, the node in question determines which is the transmission resource common to the network neighborhood in the frame 1.1. This information is obtained following the notification transmitted in step 4.3. In a next step 5.3, the communication node considered diffuses via the transmission resource common to the network neighborhood the message generated in step 5.1.

 The broadcasts via the transmission resource common to the network neighborhood can be carried out in a predetermined manner according to a fixed sequence in advance or in a random or pseudo-random manner.

 According to a second exemplary embodiment, the transmission resource common to the network neighborhood is used by a communication node considered to broadcast a discovery message, called a hello message, to indicate to the other communication nodes that it is searching for a base to attach to. This communication node considered can then receive in response via the transmission resource common to the network neighborhood at least one neighborhood message, as previously mentioned, broadcast by the node (s) of the network neighborhood having received the hello message.

 Other topology control messages can thus be transmitted according to one and / or the other of these exemplary embodiments.

 Fig. 6 schematically illustrates a second algorithm for using the transmission resource common to the network neighborhood. The transmission resource common to the network neighborhood is then used to broadcast information about the transmission conditions and thus accelerate their transmission in the communication system.

 In a step 6. 1, the communication node considered detects a change in transmission conditions, or at least determines these conditions. In particular, when these transmission conditions can cause the loss of at least one transmission channel, the communication node considered determines which is the common transmission resource in the network neighborhood in the frame 1.1, in a subsequent step 6.2. This information is obtained following the notification transmitted in step 4.3.

 In a next step 6.3, the communication node considered diffuses via the transmission resource common to the network neighborhood a message comprising information representative of the transmission conditions, or changes in transmission conditions, determined in step 6.1.

Such a broadcast mode via the transmission resource common to the network neighborhood is particularly effective when there is a loss of the transmission channel. communication between the communication node considered and the base to which it is attached or between the communication node considered and the handset (s) which is (are) attached.

 When the transmission condition changes relate to a degradation of the transmissions via the common network neighborhood resource, the communication node considered transmits the message to the master node 2.1 using a base-to-base escalation of the communication tree .

 When the transmission condition changes concern a degradation of the transmissions via a part of the common network neighborhood resource, the communication node considered transmits the message via the other part of the common network neighborhood resource.

 The process of FIG. 6 may further be used by a base to indicate to nodes in the network neighborhood that it is congested.

 Fig. 7 schematically illustrates a resynchronization algorithm using information broadcast via the transmission resource common to the network neighborhood.

 In a step 7.1, the communication node considered detects a loss of communication channel with the base to which it is attached.

 In a next step 7.2, the communication node in question obtains information broadcast via the transmission resource common to the network neighborhood and which is intended to make it possible to resynchronize on another basis. This information is that contained in the neighborhood messages previously mentioned in connection with FIG. 5. As already mentioned, these messages can be transmitted periodically by the communication nodes or be transmitted in response to a hello message transmitted by the communication node in question.

 In a next step 7.3, the communication node considered uses the information contained in the received neighborhood messages to establish a communication channel with another base.

 Fig. 8 schematically illustrates a network neighborhood connectivity improvement algorithm using information broadcast via the transmission resource common to the network neighborhood.

In a step 8.1, the communication node in question obtains information broadcast via the transmission resource common to the network neighborhood and which makes it possible to obtain a description of the topology of the network constituted by the communication nodes. This information is that contained in the neighborhood messages previously mentioned in connection with FIG. 5. In an alternative embodiment, the communication node considered receives from another communication node a message comprising a transmission condition change information, as indicated above in relation to FIG. 6.

 In a next step 8.2, the communication node considered detects a loss of connectivity with a communication node, that is to say that the messages received by the communication node considered show that the communication node having transmitted them has detected a drop in communication quality that can lead to the loss of at least one communication channel.

 In a next step 8.3, the communication node considered verifies if it does not already have the role of a base, and if it is not the case, it takes the role of a base and activates a tag in result.

 In a next step 8.4, the communication node considered diffuses via the transmission resource common to the network neighborhood a neighborhood message, as presented previously in relation to FIG. 5, indicating the activation of this tag and providing the information for synchronization.

 In a particular embodiment, in addition to implementing a transmission resource common to the network neighborhood, each database can implement a transmission resource common to its cell, and allow the handsets of its cell to access this resource. .

 The common transmission resource to a cell is preferably the elementary communication unit 1.6 which is complementary in the second part 1.3 of that used in the first part 1.2 of the frame 1.1 by the base for transmitting the beacon signals. In the representation of FIG. 1, for beacon signals transmitted on a given carrier frequency in a time interval N, the transmission resource common to the cell corresponds to the time interval N + 12 for this same carrier frequency. This common transmission resource relates to the handsets of the cell and has a predefined position relative to a resource used by the base to transmit a beacon signal. Its access is, for the handsets of the cell, similar to that of the common network neighborhood resource. It can also be sequentially predefined in time.

The common transmission resource to a cell can be used by a communication node of this cell to broadcast a neighborhood message, such as as previously presented in connection with FIG. 5. The communication node acting as a base for this cell can relay the transmitted information via the common transmission resource to the other nodes of the cell. The communication node acting as a base for this cell can relay the transmitted information via the common transmission resource at the higher hierarchical level. This is for example the case when the transmission resource common to the cell is used to broadcast information relating to the conditions, or changes in conditions, of transmission.

 The communication node acting as a base can detect a situation of scrambling, fast masking or fast attenuation, thanks to the neighborhood messages transmitted by the handsets of its cell, and thus decide to change the elementary communication unit 1.6 to transmit his tag. The same method can be implemented from neighborhood messages transmitted by the handsets of this cell via the transmission resource common to the network neighborhood.

 In a particular embodiment, the bases of the communication system are adapted to not transmit their beacon in the same time interval (s) as the transmission resource common to the network neighborhood. When a base changes its basic communication unit 1.6 to transmit its beacon, it preferably makes sure to select a time interval distinct from that or those of the transmission resource common to the network neighborhood. When the master node changes elementary communication unit 1.6 to define the transmission resource common to the network neighborhood, it preferably makes sure to select a time interval distinct from those used by the databases to transmit their tags. Such information can be sent back to the master node by going up the hierarchical tree.

Claims

1) Communication system comprising communication nodes (2.1; 2.2; 2.3; 2.4; 2.5; 2.6) communicating via frames (1.1) of multiple access type by time division and by frequency division, said nodes forming a network hierarchical cellular radio defining hierarchical levels each comprising a base (2.3) and at least one handset (2.4; 2.5), said system being adapted so that the communication nodes are authorized to communicate via the base of their hierarchical level, characterized in what a communication node (2.1), called master node, comprises:

 means for selecting (4.2) in each of said frames a transmission resource common to said communication nodes, said transmission resource common to the network neighborhood;

 means for broadcasting (4.3) to said communication nodes, through the hierarchical levels via their respective bases, information representative of the selected common transmission resource;

 and in that said system is adapted to allow said communication nodes to broadcast messages via the selected common transmission resource.

2) A communication system according to claim 1, characterized in that said master node comprises means for obtaining (4.1) information representative of transmission conditions between said communication nodes and in that the means for selecting the common transmission resource in the neighborhood network are adapted to perform the selection according to said information obtained.

3) Communication system according to claim 2, characterized in that said communication nodes comprise means for determining (6.1) transmission conditions in said communication system and means for transmitting (6.3) messages comprising information representative of conditions of transmission, or change of transmission conditions either via the transmission resource common to the network neighborhood, or via the base of their hierarchical level. 4) A communication system according to any one of claims 1 to 3, characterized in that said communication nodes comprise means for broadcasting (5.3) via the transmission resource common to the network neighborhood messages with synchronization information identifying a resource of said frames used to transmit a beacon signal.

5) A communication system according to any one of claims 1 to 4, characterized in that, said communication nodes having handset and base functions, said communication nodes comprise:

 means for detecting (8.2) a risk of loss of connectivity with a communication node,

 means for activating (8.3) a beacon signal, when a risk of loss of connectivity is detected;

means for broadcasting (8.4) via the transmission resource common to the network neighborhood a message comprising synchronization information identifying a resource of said frames, used to transmit said beacon signal. 6) A communication system according to any one of claims 1 to 5, characterized in that the base of each hierarchical level comprises means for authorizing the communication nodes of its hierarchical level to broadcast messages via a common transmission resource audit hierarchical level. 7) A communication system according to claim 6, characterized in that the common transmission resource at each hierarchical level corresponds to a resource of said frames having a predefined position relative to a resource used by the base of said hierarchical level to transmit a beacon signal . 8) Communication system according to any one of claims 6 and 7, characterized in that the base of each hierarchical level comprises means for changing the resource of said frames, used to transmit a beacon signal, based on messages received via the common transmission resource at its hierarchical level or via the transmission resource common to the network neighborhood. 9) Communication system according to any one of claims 6 to 8, characterized in that said system is adapted so that the bases transmit their beacon signal in a time interval distinct from each time interval defining the transmission resource common to the neighborhood network.

10) Communication method in a communication system comprising communication nodes (2.1; 2.2; 2.3; 2.4; 2.5; 2.6) communicating via time division multiple access frames (1.1), said nodes forming a hierarchical cellular radio network defining hierarchical levels each comprising a base (2.3) and at least one handset (2.4; 2.5), said system being adapted so that the communication nodes are authorized to communicate via the base of their hierarchical level, characterized in that a communication node (2.1), said master node, performs steps of:

 selecting (4.2) in each of said frames a transmission resource common to said communication nodes, said transmission resource common to the network neighborhood;

 - broadcasting (4.3) to said communication nodes, through the hierarchical levels via their respective bases, information representative of the selected common transmission resource;

 and in that said method is such that said communication nodes are allowed to broadcast messages via the selected common transmission resource. 11) Computer program, characterized in that it comprises instructions for implementing, by a communication node, the method according to claim 10, when said program is executed by a processor (3.2) of said communication node. 12) Storage means, characterized in that they store a computer program comprising instructions for implementing, by a communication node, the method according to claim 10, when said program is executed by a processor (3.2) said communication node.